CN117884063A - Chemical polymerization kettle with automatic feeding mechanism and use method of polymerization kettle - Google Patents
Chemical polymerization kettle with automatic feeding mechanism and use method of polymerization kettle Download PDFInfo
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- CN117884063A CN117884063A CN202410306105.3A CN202410306105A CN117884063A CN 117884063 A CN117884063 A CN 117884063A CN 202410306105 A CN202410306105 A CN 202410306105A CN 117884063 A CN117884063 A CN 117884063A
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- 238000006116 polymerization reaction Methods 0.000 title claims abstract description 91
- 239000000126 substance Substances 0.000 title claims abstract description 33
- 238000000034 method Methods 0.000 title claims abstract description 12
- 239000002994 raw material Substances 0.000 claims abstract description 71
- 239000012295 chemical reaction liquid Substances 0.000 claims abstract description 30
- 239000007788 liquid Substances 0.000 claims abstract description 14
- 239000000463 material Substances 0.000 claims description 76
- 238000004891 communication Methods 0.000 claims description 10
- 230000006835 compression Effects 0.000 claims description 6
- 238000007906 compression Methods 0.000 claims description 6
- 230000015572 biosynthetic process Effects 0.000 claims description 3
- 238000007599 discharging Methods 0.000 claims description 3
- 238000007086 side reaction Methods 0.000 claims description 3
- 238000006243 chemical reaction Methods 0.000 description 14
- 230000000694 effects Effects 0.000 description 4
- 230000008093 supporting effect Effects 0.000 description 4
- 230000000903 blocking effect Effects 0.000 description 3
- 238000004519 manufacturing process Methods 0.000 description 2
- 230000002265 prevention Effects 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000003139 buffering effect Effects 0.000 description 1
- 238000001125 extrusion Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 230000000149 penetrating effect Effects 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 230000035939 shock Effects 0.000 description 1
- 239000002699 waste material Substances 0.000 description 1
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P20/00—Technologies relating to chemical industry
- Y02P20/141—Feedstock
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Abstract
The invention relates to the field of chemical polymerization kettle feeding, in particular to a chemical polymerization kettle with an automatic feeding mechanism, which comprises a polymerization kettle body, a feeding pipeline and a feeding pipeline, wherein a feeding port is formed in the top of the polymerization kettle body, one end of the feeding pipeline is fixedly inserted into the feeding port, one end of the feeding pipeline is communicated with the outer end of the feeding pipeline, the automatic feeding mechanism further comprises an anti-blocking component and an anti-splashing component, the anti-splashing component is provided with an ultrasonic sensor for detecting the liquid level of reaction liquid in the polymerization kettle body, and the anti-splashing component is used for driving raw materials to stably fall down to prevent the raw materials from splashing due to the contact of the raw materials and the reaction liquid, so that the raw materials are lost and unevenly mixed. The invention also relates to a using method of the polymerization kettle.
Description
Technical Field
The invention relates to the field of chemical polymerization kettle feeding, in particular to a chemical polymerization kettle with an automatic feeding mechanism, and further relates to a use method of the polymerization kettle.
Background
At present, a conveying belt, a screw conveyer, a vacuum material sucking machine and the like can be generally adopted in a feeding mode when the chemical polymerization kettle is used for feeding, and in the feeding process, the problem that the material self-reaction is influenced due to splashing occurs in the feeding process because of the longer distance between the liquid level of the reaction liquid in the chemical polymerization kettle and a feeding port, so that the reaction of the material in the chemical polymerization kettle is not facilitated, when the material splashes, the material can be splashed to the inner wall of the chemical polymerization kettle, the reaction substances cannot be uniformly mixed, the reaction rate is reduced, the non-uniform reaction condition can lead to unsatisfactory reaction effect, and the product quality is reduced.
The utility model provides a take automatic feeding device's reation kettle of China patent CN116617945B that is presently disclosed, includes the reation kettle body, the top fixed mounting of reation kettle body has the feed inlet, and the feed inlet is the integral type by a plurality of baffles and constitutes, the inner wall of feed inlet is provided with the material frame body of throwing, the outer wall of material frame body is provided with stop gear, and stop gear is used for carrying out the position to the material frame body of throwing spacing, the inside of feed inlet runs through has the oblique shape delivery plate that is used for carrying out the material to the material frame body of throwing, and the upper surface of oblique shape delivery plate is provided with the conveyer belt, and the conveyer belt passes through external controller control, equal fixed mounting in outer wall both sides of feed inlet has the bracing piece, the top fixed mounting of bracing piece has the mount pad, the equal fixedly connected with connecting rod in outer wall both sides of material frame body, the outer peripheral face of connecting rod is connected with stay cord one, the top of stay cord one sets up in the mount pad.
According to the above patent, the pull rope is gradually stretched to be in a straight state from a loose state, when the pull rope is in the straight state, the feeding frame body does not move any more, the feeding frame body is close to the upper part of the mixing surface in the reaction kettle, then the materials in the feeding frame body can fall into the reaction cavity, the function of automatic feeding can be achieved through the design, the distance between the mixing surface and the feeding frame body is reduced, the problem that the material self reaction is influenced due to splashing in the feeding process because the distance between the feeding frame body and the mixing surface is long is avoided, however, the distance between the mixing surface and the feeding frame body can be reduced in a mode that the feeding frame body is close to the mixing surface, but the feeding quantity cannot be controlled, the materials can be accumulated on the mixing surface, the movement range of the stirrer is limited, and the uniformity and the reaction effect of the mixing are influenced.
Disclosure of Invention
According to the invention, the splash-preventing assembly drives raw materials to stably fall, so that the condition that raw materials are lost and unevenly mixed due to splash caused by contact of the raw materials and reaction liquid is prevented, and blocked substances are periodically removed through the blockage-preventing assembly along with continuous input of the raw materials into a feed pipeline and a feeding pipeline, so that smoothness is ensured, and the reaction efficiency and the product quality are improved.
In order to solve the problems in the prior art, the invention provides a chemical polymerization kettle with an automatic feeding mechanism, which comprises a polymerization kettle body, a feeding pipeline and a feeding pipeline, wherein a feeding port is formed in the top of the polymerization kettle body, one end of the feeding pipeline is fixedly inserted into the feeding port, the other end of the feeding pipeline extends outwards and upwards, one end of the feeding pipeline is communicated with the outer end of the feeding pipeline, the other end of the feeding pipeline extends vertically and downwards, the automatic feeding mechanism further comprises an anti-blocking component and an anti-splashing component, the anti-blocking component is arranged at the communication position between the feeding pipeline and the feeding pipeline, the anti-splashing component is arranged in the polymerization kettle body and is connected with the feeding pipeline, and an ultrasonic sensor for detecting the liquid level of a reaction liquid in the polymerization kettle body is arranged on the anti-splashing component.
Preferably, the splash prevention assembly is provided with a vertical material pipe and a spiral material pipe, the vertical material pipe is coaxially arranged at the upper half part of the polymerization kettle body, the upper end of the vertical material pipe is fixedly connected with the top of the polymerization kettle body, a communication pipeline is communicated between the vertical material pipe and the feeding pipeline, the spiral material pipe is arranged below the vertical material pipe around the inner wall of the polymerization kettle body, and the spiral material pipe is communicated with the lower end of the vertical material pipe.
Preferably, the lower extreme downwardly extending of vertical material pipe has the extension pipe, and the upper end of spiral material pipe is equipped with the feed pipe cover of cover on the extension pipe, and the lower extreme of spiral material pipe just is located its central point and has the ejection of compact mouth of pipe, and the spiral material pipe can be along its axis direction removal for vertical material pipe, and the inboard upper half of polymeric kettle body is equipped with the height-adjusting driver that is used for driving the spiral material pipe and removes.
Preferably, the height-adjusting driver is provided with a lantern ring, a first electromagnet and a second electromagnet, the lantern ring is coaxially sleeved in the polymerization kettle body, the inner wall of the lantern ring is provided with a spiral track for embedding a spiral material pipe, the first electromagnet is fixedly arranged on the inner side wall of the polymerization kettle body, the first electromagnet is located above the lantern ring, the second electromagnet is fixedly arranged on the lantern ring and corresponds to the position of the first electromagnet, and the first electromagnet and the second electromagnet are electrically connected.
Preferably, a first connecting rod and a second connecting rod are arranged between the inner wall of the polymerization kettle body and the upper end of the lantern ring, one end of the first connecting rod is rotationally connected with the inner wall of the polymerization kettle body, one end of the second connecting rod is rotationally connected with the upper end of the lantern ring, the other end of the first connecting rod is rotationally connected with the other end of the second connecting rod, and hinge parts for rotationally connecting the ends of the first connecting rod and the second connecting rod are respectively arranged on the polymerization kettle body and the lantern ring.
Preferably, an annular step fixedly sleeved in the polymerization kettle body is arranged below the lantern ring, and a compression spring sleeved in the polymerization kettle body is fixedly connected between the annular step and the lower end of the lantern ring.
Preferably, the anti-blocking assembly is provided with an elastic pull rope and a rotary column, the elastic pull rope is arranged in a feeding pipeline and a feeding pipeline, one end of the elastic pull rope is fixedly connected with the side wall of the feeding pipeline, the other end of the elastic pull rope sequentially penetrates through the feeding pipeline and the communicating pipeline to be fixedly connected with the upper end of the vertical material pipe, the feeding pipeline and the vertical material pipe are respectively provided with a first fixing part and a second fixing part which are fixedly connected with the end part of the elastic pull rope, the rotary column is rotationally connected to the communicating part between the feeding pipeline and the feeding pipeline, the diameter of the rotary column is smaller than the inner diameters of the feeding pipeline and the feeding pipeline, and the middle part of the rotary column is provided with a perforation through which the elastic pull rope penetrates.
Preferably, the upper end of the rotary column is provided with an upper end extension shaft extending upwards, the end part of the upper end extension shaft is sleeved with a fixed end sleeve fixedly connected with a communicating part between the feeding pipeline and the feeding pipeline, the inner side of the fixed end sleeve is fixedly provided with a third electromagnet, the side wall of the upper end extension shaft is fixedly provided with a fourth electromagnet corresponding to the third electromagnet, and the third electromagnet and the fourth electromagnet are electrically connected.
Preferably, the lower end of the rotary column is provided with a lower end extension shaft extending downwards, the end part of the lower end extension shaft is provided with an end ring, and a torsion spring sleeved on the lower end extension shaft is fixedly connected between the end ring and the communicating part between the feeding pipeline and the feeding pipeline.
The invention also provides a using method of the polymerization kettle, which comprises the following steps:
S1, starting a suction pump to automatically send raw materials into a feeding pipeline, and pushing the raw materials into a polymerization kettle body through a feeding pipeline along with continuous pressurization;
s2, sensing the liquid level of the reaction liquid in the polymerization kettle body through an ultrasonic sensor;
S3, driving the raw materials to fall through the splash-preventing assembly according to the liquid level of the reaction liquid, reducing the falling height of the raw materials corresponding to the reaction liquid, and intensively inputting, so as to reduce side reactions and uneven product formation;
s4, the blockage in the feeding pipeline and the feeding pipeline is removed regularly through the anti-blockage assembly, and normal conveying of raw materials is guaranteed.
Compared with the prior art, the application has the beneficial effects that:
1. according to the invention, through the communication between the feeding pipeline and the polymerization kettle body, raw materials are conveyed into the polymerization kettle body, and the splash-preventing assembly drives the raw materials to stably fall, so that the conditions of raw material loss and uneven mixing caused by splash of the raw materials in contact with reaction liquid are prevented, and the raw materials are continuously conveyed into the feeding pipeline and the feeding pipeline along with the conditions of blockage, so that the blocked materials are periodically removed through the blockage-preventing assembly, the smoothness is ensured, the automatic and normal conveying of the raw materials is realized, and the reaction efficiency and the quality of products are improved.
2. According to the invention, the raw materials are fed through the spiral material pipe, so that the raw materials are continuously conveyed along the spiral track, the conveying flow and the conveying speed of the raw materials are convenient to control, compared with a direct feeding mode, the situation that the raw materials are damaged and mixed unevenly due to splashing caused by contact of the raw materials and the reaction liquid is avoided, stable feeding of the raw materials is realized, the production quality is improved, and the raw material loss is reduced.
3. According to the invention, the height-adjusting driver drives the spiral material pipe to move relative to the vertical material pipe, so that the discharge pipe orifice of the spiral material pipe is driven to be close to the reaction liquid, the phenomenon that raw materials are splashed when being contacted with the reaction liquid is prevented, the raw materials and the reaction liquid are ensured to be uniformly mixed and reacted, the stable conveying and uniform mixing of the raw materials are realized, the production efficiency and the product quality are improved, and the inner wall of the polymerization kettle body is convenient to clean.
Drawings
FIG. 1 is a schematic perspective view of a chemical polymerization kettle with an automatic feeding mechanism.
FIG. 2 is a partial perspective view of a chemical polymerization kettle with an automatic feeding mechanism.
Fig. 3 is a partial plan sectional view of a chemical polymerization kettle with an automatic loading mechanism.
FIG. 4 is a schematic perspective view of a chemical polymerization reactor with an automatic loading mechanism for removing the bulk of the reactor.
Fig. 5 is an enlarged schematic view at a of fig. 3.
Fig. 6 is an enlarged schematic view at B of fig. 3.
Fig. 7 is an enlarged schematic view at C of fig. 4.
Fig. 8 is an enlarged schematic view at D of fig. 3.
Fig. 9 is a schematic perspective view of an anti-clogging assembly of a chemical polymerization kettle with an automatic feeding mechanism.
Fig. 10 is a schematic exploded view of a three-dimensional structure of an anti-clogging assembly of a chemical polymerization kettle with an automatic feeding mechanism.
The reference numerals in the figures are: 1-a polymerization kettle body; 2-feeding pipeline; 21-a communication pipe; 3-a feed pipe; 4-an anti-clogging assembly; 41-elastic pull ropes; 411-a first fixing portion; 412-a second securing portion; 42-spin columns; 421-piercing; 43-upper end extension shaft; 431-fixing the end sleeve; 432-a third electromagnet; 433-fourth electromagnet; 44-a lower end extension shaft; 441-end rings; 442-torsion spring; 5-a splash prevention assembly; 51-vertical feed pipe; 511-extension tube; 52-spiral material pipe; 521-feeding pipe sleeve; 522-a discharge nozzle; 53-a step-up driver; 531-collar; 5311 a first link; 5312 a second link; 5313 a hinge; 532—a first electromagnet; 533-a second electromagnet; 534-an annular step; 5341-a compression spring; 6-ultrasonic sensor.
Detailed Description
The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.
Referring to fig. 1-4, a chemical polymerization kettle with automatic feeding mechanism, including polymerization kettle body 1, material loading pipeline 2 and feed pipeline 3, the feed inlet has been seted up at the top of polymerization kettle body 1, the fixed plug of one end of material loading pipeline 2 is established in the feed inlet, the other end of material loading pipeline 2 outwards upwards extends, the one end of feed pipeline 3 communicates with the outer end of material loading pipeline 2, the other end of feed pipeline 3 vertically downwardly extending, automatic feeding mechanism still includes prevents blockking up subassembly 4 and prevents splashing subassembly 5, prevent blockking up subassembly 4 and set up the intercommunication department between material loading pipeline 2 and feed pipeline 3, prevent splashing the subassembly 5 and be connected at the inside of polymerization kettle body 1 and prevent splashing subassembly 5 and feed pipeline 2, prevent splashing and be equipped with on the subassembly 5 and be used for detecting the ultrasonic sensor 6 of the liquid level of reaction liquid in the polymerization kettle body 1.
When the raw materials are put into the polymerization kettle body 1, raw materials are pumped through the suction pump, the suction pump is not shown in the drawing, the suction pump is connected with the feeding pipeline 3, raw materials are sucked into the feeding pipeline 3, the raw materials enter the feeding pipeline 2 along with continuous pressurization, and then enter the splash preventing assembly 5 through the feeding pipeline 2, the liquid level of the reaction liquid in the polymerization kettle body 1 is detected according to the ultrasonic sensor 6, the splash preventing assembly 5 drives the raw materials to be close to the reaction liquid and is intensively put into the reaction liquid, the situation that the raw materials fall from a high place to contact with the reaction liquid is avoided, the raw materials splash to the inner wall of the polymerization kettle body 1 is avoided, the generation of the raw materials cannot be uniformly mixed and local concentration gradient is avoided, the reaction rate is reduced, the loss of a part of raw materials is prevented, the phenomena of raw materials waste and cost increase are caused, the raw materials sequentially enter the polymerization kettle body 1 along with the continuous input of the feeding pipeline 3 and the feeding pipeline 2, in order to avoid the phenomenon of raw materials blocking in the feeding pipeline 3 and the feeding pipeline 2, therefore, the blockage preventing assembly 4 is periodically started, the raw materials in the feeding pipeline 3 and the feeding pipeline 2 are blocked up, and the smooth feeding of the materials in the feeding pipeline 2 are ensured.
Referring to fig. 2-4, the splash preventing assembly 5 is provided with a vertical material pipe 51 and a spiral material pipe 52, the vertical material pipe 51 is coaxially arranged at the upper half part of the polymerizer body 1, the upper end of the vertical material pipe 51 is fixedly connected with the top of the polymerizer body 1, a communicating pipeline 21 is communicated between the vertical material pipe 51 and the feeding pipeline 2, the spiral material pipe 52 is arranged below the vertical material pipe 51 around the inner wall of the polymerizer body 1, and the spiral material pipe 52 is communicated with the lower end of the vertical material pipe 51.
After the raw materials enter the feeding pipeline 2, the raw materials enter the vertical material pipe 51 through the communication pipeline 21, and along with continuous extrusion of the raw materials, the raw materials enter the spiral material pipe 52, and are conveyed downwards in the spiral material pipe 52 along a spiral track until being intensively thrown in the polymerization kettle body 1, so that the situation that the raw materials directly fall from a high place to be in contact with reaction liquid to splash is avoided, the uniform mixing of the raw materials and the generation of local concentration gradient are ensured, the flow and the throwing speed of the raw materials are favorably controlled, the concentrated throwing of the spiral material pipe 52 can reduce the loss of the raw materials, and compared with the scattered throwing mode, the concentrated throwing can enable the raw materials to enter the treatment equipment more intensively, and the splashing and scattering of the raw materials in the throwing process are reduced.
Referring to fig. 3 to 5, an extension pipe 511 extends downward from the lower end of the vertical pipe 51, a feeding pipe sleeve 521 sleeved on the extension pipe 511 is provided at the upper end of the spiral pipe 52, a discharging pipe orifice 522 is provided at the center point of the lower end of the spiral pipe 52, the spiral pipe 52 is movable along the axial direction thereof with respect to the vertical pipe 51, and a height adjusting driver 53 for driving the movement of the spiral pipe 52 is provided at the upper half of the inner side of the polymerizer body 1.
When the ultrasonic sensor 6 detects the liquid level of the reaction liquid in the polymerization kettle body 1, a signal is transmitted to a controller, the controller is not shown in the figure, and the controller controls the height-adjusting driver 53 to start, so that the spiral pipe 52 is driven to move relative to the vertical pipe 51, the discharging pipe orifice 522 of the spiral pipe 52 is driven to be close to the liquid level of the reaction liquid, and the feeding pipe sleeve 521 on the spiral pipe 52 and the extension pipe 511 on the vertical pipe 51 are in a communicating state, so that raw materials are guaranteed to be conveyed into the spiral pipe 52, a material leakage phenomenon is avoided, and splashing is avoided until the raw materials fall into the reaction liquid.
Referring to fig. 3-7, the height-adjusting driver 53 is provided with a collar 531, a first electromagnet 532 and a second electromagnet 533, the collar 531 is coaxially sleeved in the polymerizer body 1, the inner wall of the collar 531 is provided with a spiral track for embedding the spiral pipe 52, the first electromagnet 532 is fixedly arranged on the inner side wall of the polymerizer body 1, the first electromagnet 532 is located above the collar 531, the second electromagnet 533 is fixedly arranged on the collar 531 and corresponds to the position of the first electromagnet 532, and the first electromagnet 532 and the second electromagnet 533 are electrically connected.
When the height-adjusting driver 53 is started, the first electromagnet 532 and the second electromagnet 533 are simultaneously energized, and the electrodes of the first electromagnet 532 and the second electromagnet 533 are changed according to the principle that the same poles repel each other and the different poles attract each other, so that the movement of the collar 531 is controlled, and the spiral pipe 52 is supported in the spiral track on the collar 531, so that the movement of the collar 531 drives the spiral pipe 52 to move together, thereby controlling the raw material throwing height, and the spiral track on the collar 531 can play a supporting role on the spiral pipe 52, so that the stability of the raw material transported in the spiral pipe 52 is maintained, and the shaking and swinging of the spiral pipe 52 are reduced.
Referring to fig. 3 to 7, a first link 5311 and a second link 5312 are provided between the inner wall of the polymerizer body 1 and the upper end of the collar 531, one end of the first link 5311 is rotatably connected to the inner wall of the polymerizer body 1, one end of the second link 5312 is rotatably connected to the upper end of the collar 531, the other end of the first link 5311 is rotatably connected to the other end of the second link 5312, and hinge portions 5313 for rotatably connecting the ends of the first link 5311 and the second link 5312 are provided on the polymerizer body 1 and the collar 531, respectively.
When the collar 531 moves, the first and second links 5311 and 5312 also follow the movement, and by this linkage, the collar 531 is prevented from falling. The supporting effect of the collar 531 is enhanced so that the helical tube 52 is more stable during the movement.
Referring to fig. 6, an annular step 534 fixedly sleeved in the polymerizer body 1 is provided below the collar 531, and a compression spring 5341 fixedly sleeved in the polymerizer body 1 is connected between the annular step 534 and the lower end of the collar 531.
The annular step 534 provides a supporting surface for the collar 531, so that the collar 531 is further prevented from falling off in the moving process, and the connection between the collar 531 and the annular step 534 through the compression spring 5341 provides buffering and shock absorbing effects between the collar 531 and the annular step 534, so that unstable factors caused by vibration or impact of the polymerization kettle body 1 are reduced or prevented, and in addition, the compression spring 5341 also has a supporting effect on the collar 531, so that the movement of the collar 531 is more stable, and the collar 531 is facilitated to drive the spiral pipe 52 to return to the original position.
Referring to fig. 2, 3, 8,9 and 10, the anti-blocking assembly 4 is provided with an elastic pull rope 41 and a rotating column 42, the elastic pull rope 41 is arranged in the feeding pipeline 2 and the feeding pipeline 3, one end of the elastic pull rope 41 is fixedly connected with the side wall of the feeding pipeline 3, the other end of the elastic pull rope 41 sequentially penetrates through the feeding pipeline 2 and the communicating pipeline 21 to be fixedly connected with the upper end of the vertical pipeline 51, a first fixing part 411 and a second fixing part 412 which are fixedly connected with the end parts of the elastic pull rope 41 are respectively arranged on the feeding pipeline 3 and the vertical pipeline 51, the rotating column 42 is rotatably connected to the communicating part between the feeding pipeline 3 and the feeding pipeline 2, the diameter of the rotating column 42 is smaller than the inner diameters of the feeding pipeline 3 and the feeding pipeline 2, and a through hole 421 for the elastic pull rope 41 to penetrate is formed in the middle of the rotating column 42.
When the materials blocked in the feeding pipeline 3 and the feeding pipeline 2 are removed periodically, the elastic pull rope 41 is pulled through the rotation of the rotary column 42, so that the elastic pull rope 41 penetrating through the through holes 421 of the rotary column 42 moves along with the materials, the position and the tension of the elastic pull rope 41 are adjusted, and when the elastic pull rope 41 stops pulling and resets, a certain rebound force can be generated due to the elastic effect of the elastic pull rope, so that the blocked materials can be helped to be broken, the blocking occurrence can be reduced or prevented, and the smoothness of the feeding pipeline 3 and the feeding pipeline 2 can be ensured.
Referring to fig. 8 to 10, the upper end of the rotary column 42 has an upper end extension shaft 43 extending upward, a fixed end cap 431 fixedly connected to the connection between the feed pipe 3 and the feed pipe 2 is sleeved on the end of the upper end extension shaft 43, a third electromagnet 432 is fixedly provided on the inner side of the fixed end cap 431, a fourth electromagnet 433 is fixedly provided on the side wall of the upper end extension shaft 43 and at a position corresponding to the third electromagnet 432, and the third electromagnet 432 and the fourth electromagnet 433 are electrically connected.
When the rotary column 42 is rotated and started, the third electromagnet 432 and the fourth electromagnet 433 are simultaneously electrified, the rotary column 42 is controlled to rotate according to the principle that like poles repel each other, so that the elastic pull rope 41 is twisted, after the rotary column 42 is controlled to stop rotating, the third electromagnet 432 and the fourth electromagnet 433 stop being electrified, the elastic pull rope 41 is restored to a normal state, and at the moment, the elastic pull rope 41 generates elastic force to impact on blocking substances, so that the blocked substances can be removed.
Referring to fig. 8 to 10, the lower end of the rotary column 42 has a lower end extension shaft 44 extending downward, the end of the lower end extension shaft 44 has an end ring 441, and a torsion spring 442 sleeved on the lower end extension shaft 44 is fixedly connected between the end ring 441 and the communication place between the feeding pipe 3 and the feeding pipe 2.
When the rotary column 42 rotates, the torsion spring 442 is in a torsion state, and when the rotary column 42 stops rotating, the torsion spring 442 returns to a normal state, so that the rotary column 42 is immediately driven to rotate, and the elastic pull rope 41 is ensured to generate elastic force.
The application method of the polymerization kettle is applied to a chemical polymerization kettle with an automatic feeding mechanism, and comprises the following steps:
S1, starting a suction pump to automatically send raw materials into a feed pipeline 3, and pushing the raw materials into a polymerization kettle body 1 through a feeding pipeline 2 along with continuous pressurization;
S2, sensing the liquid level of the reaction liquid in the polymerization kettle body 1 through an ultrasonic sensor 6;
S3, driving the raw materials to fall through the splash-preventing assembly 5 according to the liquid level of the reaction liquid, reducing the falling height of the raw materials corresponding to the reaction liquid, and intensively inputting, so as to reduce side reactions and uneven product formation;
S4, the blockage in the feeding pipeline 3 and the feeding pipeline 2 is removed periodically through the anti-blockage assembly 4, so that normal conveying of raw materials is guaranteed.
According to the invention, through the communication between the feed pipeline 3 and the feeding pipeline 2 and the polymerization kettle body 1, raw materials are conveyed into the polymerization kettle body 1, and the raw materials are driven to stably fall through the splash preventing assembly 5, so that the conditions of raw material loss and uneven mixing caused by splash when the raw materials are contacted with reaction liquid are prevented, and the blocked materials are periodically removed through the blockage preventing assembly 4 along with the continuous input of the raw materials into the feed pipeline 3 and the feeding pipeline 2, so that blockage is avoided, smoothness is ensured, and the reaction efficiency and the quality of products are improved.
The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of the invention should be assessed as that of the appended claims.
Claims (10)
1. A chemical polymerization kettle with an automatic feeding mechanism comprises a polymerization kettle body (1), a feeding pipeline (2) and a feeding pipeline (3);
A feeding port is formed in the top of the polymerization kettle body (1);
One end of the feeding pipeline (2) is fixedly inserted into the feeding port, and the other end of the feeding pipeline (2) extends outwards and upwards;
one end of the feed pipeline (3) is communicated with the outer end of the feeding pipeline (2), and the other end of the feed pipeline (3) extends vertically downwards;
the automatic feeding mechanism is characterized by further comprising an anti-blocking assembly (4) and an anti-splashing assembly (5);
the anti-blocking assembly (4) is arranged at the communication part between the feeding pipeline (2) and the feeding pipeline (3);
The splash-preventing assembly (5) is arranged in the polymerization kettle body (1) and the splash-preventing assembly (5) is connected with the feeding pipeline (2);
The splash-proof assembly (5) is provided with an ultrasonic sensor (6) for detecting the liquid level of the reaction liquid in the polymerization kettle body (1).
2. A chemical polymerization kettle with an automatic feeding mechanism according to claim 1, characterized in that the splash preventing assembly (5) is provided with a vertical pipe (51) and a spiral pipe (52);
the vertical material pipe (51) is coaxially arranged at the upper half part of the polymerization kettle body (1), the upper end of the vertical material pipe (51) is fixedly connected with the top of the polymerization kettle body (1), and a communication pipeline (21) is communicated between the vertical material pipe (51) and the feeding pipeline (2);
The spiral material pipe (52) is arranged below the vertical material pipe (51) around the inner wall of the polymerization kettle body (1), and the spiral material pipe (52) is communicated with the lower end of the vertical material pipe (51).
3. The chemical polymerization kettle with the automatic feeding mechanism according to claim 2, wherein an extension pipe (511) is downwardly extended from the lower end of the vertical material pipe (51), a feeding pipe sleeve (521) sleeved on the extension pipe (511) is arranged at the upper end of the spiral material pipe (52), a discharging pipe orifice (522) is arranged at the lower end and the center point of the spiral material pipe (52), the spiral material pipe (52) can move along the axial direction relative to the vertical material pipe (51), and a height adjusting driver (53) for driving the spiral material pipe (52) to move is arranged at the upper half part of the inner side of the polymerization kettle body (1).
4. A chemical polymerization kettle with automatic feeding mechanism according to claim 3, characterized in that the height-adjusting driver (53) is provided with a collar (531), a first electromagnet (532) and a second electromagnet (533);
the lantern ring (531) is coaxially sleeved in the polymerization kettle body (1), and the inner wall of the lantern ring (531) is provided with a spiral track for embedding the spiral material pipe (52);
the first electromagnet (532) is fixedly arranged on the inner side wall of the polymerization kettle body (1), and the first electromagnet (532) is positioned above the lantern ring (531);
The second electromagnet (533) is fixedly arranged on the lantern ring (531) and corresponds to the first electromagnet (532), and the first electromagnet (532) and the second electromagnet (533) are electrically connected.
5. The chemical polymerization kettle with the automatic feeding mechanism according to claim 4, wherein a first connecting rod (5311) and a second connecting rod (5312) are arranged between the inner wall of the polymerization kettle body (1) and the upper end of the lantern ring (531), one end of the first connecting rod (5311) is rotationally connected with the inner wall of the polymerization kettle body (1), one end of the second connecting rod (5312) is rotationally connected with the upper end of the lantern ring (531), the other end of the first connecting rod (5311) is rotationally connected with the other end of the second connecting rod (5312), and hinge parts (5313) for rotationally connecting the ends of the first connecting rod (5311) and the second connecting rod (5312) are respectively arranged on the polymerization kettle body (1) and the lantern ring (531).
6. The chemical polymerization kettle with the automatic feeding mechanism according to claim 5, wherein an annular step (534) fixedly sleeved in the polymerization kettle body (1) is arranged below the collar (531), and a compression spring (5341) sleeved in the polymerization kettle body (1) is fixedly connected between the annular step (534) and the lower end of the collar (531).
7. A chemical polymerization kettle with an automatic feeding mechanism according to claim 2, characterized in that the anti-blocking component (4) is provided with an elastic pull rope (41) and a rotary column (42);
The elastic pull rope (41) is arranged in the feeding pipeline (2) and the feeding pipeline (3), one end of the elastic pull rope (41) is fixedly connected with the side wall of the feeding pipeline (3), the other end of the elastic pull rope (41) sequentially penetrates through the feeding pipeline (2) and the communicating pipeline (21) to be fixedly connected with the upper end of the vertical pipeline (51), and the feeding pipeline (3) and the vertical pipeline (51) are respectively provided with a first fixing part (411) and a second fixing part (412) which are fixedly connected with the end parts of the elastic pull rope (41);
The rotary column (42) is rotationally connected to the communication part between the feeding pipeline (3) and the feeding pipeline (2), the diameter of the rotary column (42) is smaller than the inner diameters of the feeding pipeline (3) and the feeding pipeline (2), and a through hole (421) for the elastic pull rope (41) to pass through is formed in the middle of the rotary column (42).
8. The chemical polymerization kettle with the automatic feeding mechanism according to claim 7, wherein the upper end of the rotary column (42) is provided with an upper end extension shaft (43) extending upwards, the end part of the upper end extension shaft (43) is sleeved with a fixed end sleeve (431) fixedly connected with a communicating part between the feeding pipeline (3) and the feeding pipeline (2), the inner side of the fixed end sleeve (431) is fixedly provided with a third electromagnet (432), the side wall of the upper end extension shaft (43) is fixedly provided with a fourth electromagnet (433) corresponding to the position of the third electromagnet (432), and the third electromagnet (432) and the fourth electromagnet (433) are electrically connected.
9. The chemical polymerization kettle with the automatic feeding mechanism according to claim 8, wherein the lower end of the rotary column (42) is provided with a lower end extension shaft (44) extending downwards, the end part of the lower end extension shaft (44) is provided with an end ring (441), and a torsion spring (442) sleeved on the lower end extension shaft (44) is fixedly connected between the end ring (441) and the communicating part between the feeding pipeline (3) and the feeding pipeline (2).
10. A method for using a polymerization kettle, which is applied to the chemical polymerization kettle with the automatic feeding mechanism as claimed in any one of claims 1 to 9, and is characterized by comprising the following steps:
S1, starting a suction pump to automatically send raw materials into a feed pipeline (3), and pushing the raw materials into a polymerization kettle body (1) through a feeding pipeline (2) along with continuous pressurization;
s2, sensing the liquid level of the reaction liquid in the polymerization kettle body (1) through an ultrasonic sensor (6);
S3, driving the raw materials to fall through the splash-preventing assembly (5) according to the liquid level of the reaction liquid, reducing the falling height of the raw materials corresponding to the reaction liquid, and intensively inputting, so as to reduce side reactions and uneven product formation;
S4, the blockage in the feeding pipeline (3) and the feeding pipeline (2) is removed regularly through the anti-blockage assembly (4), so that normal conveying of raw materials is guaranteed.
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